Toothbrush monitoring device

ABSTRACT

The invention relates to a toothbrushing monitoring device ( 18 ). In order to obtain an efficient monitoring device, the monitoring device comprises: an input device ( 21 ), an acceleration sensor, a signal conditioner, a memory, a comparator which compares the numbers of brushing cycles registered by each teeth surface specific counter during brushing with corresponding reference values maintained in said memory, and an output device ( 27 ) which indicates that the brushing of the teeth region (L-U) in question is accepted.

REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.13/816,422 filed Feb. 11, 2013 which is a 371 U.S. national stageapplication of PCT/FI2011/050690 filed Aug. 5, 2011 which claims thebenefit of the filing date of Finnish Patent Application No. 20105846filed Aug. 11, 2010.

FIELD OF THE INVENTION

This invention relates to a device for monitoring the use of atoothbrush in order to give the user feedback about brushing.

DESCRIPTION OF PRIOR ART

Previously there are known toothbrushes with monitoring devices whichgive users feedback about the brushing result. Such devices may employacceleration sensors, timers, and pressure sensors, for instance, inorder to obtain measurement data during toothbrushing.

However, to determine the brushing result, in other words how well theuser has succeeded with toothbrushing, has turned out to be achallenging task. In addition, the costs and the of the device used needto be kept within reasonable limits.

Improvements can still be made regarding the accuracy and device costsof known monitoring devices.

SUMMARY OF THE INVENTION

An object of the present invention is to provide an improved monitoringdevice for determining the result of toothbrushing. This object isachieved with a monitoring device according to independent claim 1.

This monitoring device utilizes the possibility of identifying the teethsurface that is being brushed within a teeth region on the basis of theinclination of the toothbrush as compared with the earth's gravitationduring brushing cycles. By registering the number of brushing cycleswith teeth surface specific registers, information is obtained about thenumber of brushing cycles each teeth surface within the teeth region issubjected to. The registered number of brushing cycles may then becompared with teeth surface specific reference values in order toevaluate how well the toothbrushing has succeeded. The result is amonitoring device that provides a cost-effective, space and energysaving solution for reliably monitoring toothbrushing.

BRIEF DESCRIPTION OF DRAWINGS

In the following, the present invention will be described in closerdetail by way of example and with reference to the attached drawings, inwhich

FIG. 1 illustrates teeth regions in one embodiment,

FIG. 2 illustrates an embodiment of an output device,

FIG. 3 illustrates an embodiment of a toothbrush with a monitoringdevice,

FIG. 4 illustrates a coordinate system,

FIG. 5 is a block diagram illustrating an embodiment of a monitoringdevice, and

FIG. 6 is a flow chart illustrating operation of a monitoring device.

DESCRIPTION OF AT LEAST ONE EMBODIMENT

FIG. 1 illustrates teeth regions in one embodiment and FIG. 2illustrates an embodiment of an output device 27.

In the embodiment of FIG. 1, the teeth have by way of example beendivided into four teeth regions R-U, L-U, R-D, and L-D. The teethregions, in this case quarters, may be identified as left-up L-U,left-down L-D, right-up R-U, and right-down R-D. In many cases,sufficient feedback may be given to the user of a toothbrush byindicating that one (or more) of these four regions has (have) not beenbrushed thoroughly enough.

In an embodiment, each of the four teeth regions R-U, L-U, R-D and L-Dcomprises three predefined teeth surfaces that need brushing. In FIG. 1,each region therefore comprises an outer surface 1 to 4, an innersurface 5 to 8, and a masticating surface 9 to 12.

In the following examples, the user brushes the teeth by brushing thefour teeth regions R-U, L-U, R-D, and L-D in a predetermined order, oralternatively, by indicating to the monitoring device which region ispresently being brushed. The monitoring device consequently knows theteeth region that is being brushed. However, the user may brush theteeth surfaces 1, 5, 9; 2, 6, 10; 3, 7, 11; or 4, 8, 12 within one teethregion R-U, L-U, R-D, and L-D in any desired order, even by switchingseveral times between the inner, outer and masticating surfaces whilebrushing the specific teeth region.

The output device utilized in the monitoring device may indicate thebrushing result to the user in any convenient manner, which makes itpossible for the user to determine whether or not the brushing of ateeth region R-U, L-U, R-D or L-D has been accepted. Such an outputdevice may include at least one of the following: a LED (Light EmittingDiode), a sound generator for producing sounds or music, and a speechgenerator. The output device may be physically located in a modulemoving together with a toothbrush, or alternatively such a module mayinclude a wired or wireless data transmitting interface for transmittingdata to an external output device that indicates the result of thebrushing to the user.

In the example of FIG. 2, it is by way of example assumed that theoutput device 27 may include LEDs or an LCD display with one sector 13to 16 for each teeth region shown in FIG. 1. If sector 13 is illuminatedin red on the output device of FIG. 2 after brushing, the userunderstands that region R-U of FIG. 1 requires a more thorough brushing,for instance. Similarly, if another sector 14 is illuminated in red onthe output device of FIG. 2 after brushing, the user understands thatregion L-U of FIG. 1 requires a more thorough brushing, for instance. Anacceptable brushing may be indicated by illuminating in another colour,such as green, for example. Alternatively, other colours and ways ofilluminating the indicator may be utilized in order to provide the userwith feedback, such as a flashing versus steady mode light, lit versusunlit, and the like.

If LEDs are used in the output device 27, the output device may includeone pair of LEDs for each teeth region. In such a case, each pair ofLEDs includes a LED of a first colour to indicate successful brushing ofthat quarter and a LED of a second colour to indicate an unsuccessfulbrushing of that quarter.

FIG. 3 illustrates an embodiment of a toothbrush 17 with a monitoringdevice 18 and FIG. 4 illustrates a coordinate system XYZ for a brushhead 19 of such a toothbrush.

In the embodiment of FIG. 3, the monitoring device 18 has been producedas a separate module containing the necessary electronic components anda battery, which has been embedded into a shaft of a manual toothbrush17. In this way, bristles 20 of the brush head 19 move with the brushhead 19, and the monitoring device 18 moves with each movement of thebrush head. However, this is only one example as to how a monitoringdevice 18 may be arranged in a toothbrush. Alternatively, the monitoringdevice may be an extension of the shaft of the toothbrush or connectedto the toothbrush in some other way. The brush head 19 may be detachablefrom the handle of the toothbrush 17 in order to facilitate thatdifferent persons with their own brush head use the same toothbrush 17handle.

In FIG. 3, the monitoring device is by way of example provided with aninput device 21, such as a push button, and an output device 27, asillustrated in FIG. 2. The input device may, however, be located in aseparate apparatus not shown in FIG. 3, in which case the monitoringdevice may include a wired or wireless data transmission interface 22for receiving signals from the separate input device.

For the sake of clarity, in FIG. 4 the direction of the X-axis isgenerally the same as the direction of the bristles 20 in the brush, thedirection of the Y-axis is perpendicular to the X-axis and generally thesame as the longitudinal direction of the brush head 19, which in theillustrated example is the direction of the centre line of the tubularbody of the toothbrush 17, and the Z-axis is generally directed sidewaysfrom the brush head, thus forming a 90° angle with the X- and Y-axes. Itshould, however, be observed that the exact directions of the axes arenot important to the monitoring device as such, but they are definedsolely to enable the following example to be understood.

FIG. 5 is a block diagram illustrating an example of a monitoring device18. The monitoring device may be integrated into a toothbrush, such asin FIG. 3, or alternatively consist of a separate component that isattached to a toothbrush. As a separate component, the monitoring devicemay be detached from a first toothbrush and attached to anothertoothbrush. In such a case, the monitoring device may be part of aninterchangeable toothbrush handle.

In this example, the monitoring device comprises a signal conditioner 23controlling the operation of the monitoring device 18. The signalconditioner 23 and a comparator 24 may be implemented with circuitry, acomputer programme or a combination of a computer programme andcircuitry. In the last two cases, a processor running on a computer maycarry out the tasks of the signal conditioner 23 and/or the comparator24 under control of software. The computer may be a stand-aloneprocessor, e.g. incorporated into a base device, or a general purposecomputer. The signal conditioner and the comparator may thereforephysically consist of one single part.

The signal conditioner 23 carries out low-pass and high-pass filtering,with one or more digital filters, for instance. At least one of thefilters may be of a type: y(t)=y(t−1)*(1−1/k)+x(t)/k, where y(t) isoutput at time step t, x(t) is input at time step t, and k is a filterfactor respectively. At least one of the filters may also be of a type:z(t)=x(t)−y(t), where z(t) is output at time step t, x(t) is input attime step t, and y(t) is a low-pass-filtered signal, respectively.

An acceleration sensor 25 is coupled to the device for measuringtoothbrushing patterns. A three-axis acceleration sensor 25 may beutilized to detect the inclination of the toothbrush during use, such asthe angles at which the toothbrush and the monitoring device attached tothe toothbrush are held during use as compared with the gravity of theearth. In another example, the three-axis acceleration sensor 25measures toothbrushing cyclic and/or non-cyclic motion. The accelerationsensor may be a CMA3000 available from VTI Technologies Oy, P.O. Box 27,FI-01621 Vantaa, Finland, for example. The output of a three-axisacceleration sensor may be expressed as:

a _(measured) =a+g+a _(E)  , (1)

where the output measured vector (a_(measured), three components)corresponds to the sum of the acceleration (a) of an object, thegravitation vector (g), and an error term (a_(E)) all in the localcoordinate system of the brushing monitoring device.

From equation (1), an acceleration sensor may be used to measure bothinclination (when the change in velocity a is known) and acceleration(when the gravitational acceleration in a brush frame is known). Noadditional cost-increasing and space-consuming sensor components arenecessary to track the movement or position of a toothbrush, thereforethe monitoring device may include a three-axis acceleration sensor 25 asthe only sensor. One advantage of a device using only an accelerationsensor is that the costs to produce the device are reduced. Anotheradvantage is that using an acceleration sensor with no otherdisplacement orientation or position sensors saves space. Compared withsome other approaches, a third advantage is the ultra-low powerconsumption.

In measurements carried out with the monitoring device 18, accelerationis assumed to be noise disturbing the inclination or angle measurements.During toothbrushing, the acceleration sensor 25 may measuretoothbrushing patterns, which may be recorded or supplied as data to thecomparator 24. The comparator 24 may also receive toothbrushing patternreference data, in other words reference values, from a memory 26. Thememory 26 may be a recording device that is coupled with theacceleration sensor 25 and/or the signal conditioner 23 for retainingpattern reference data. The signal conditioner 23 may perform low- andhigh-pass filtering functions as well as level triggering functions onthe acceleration data to obtain relevant brushing pattern data andparameters.

For example, tooth-brushing pattern reference data or reference values,stored in the memory 26, may be compared with data produced during anormal, daily use of a toothbrush once the use of the toothbrush hasfinished. In one example of toothbrushing pattern reference data, thetoothbrushing pattern reference data may also indicate the time used(seconds, for instance) for brushing each teeth region, the number ofbrushing cycles per teeth region, and the brushing order (transfer fromone position to another). The comparison between tooth brushing patterndata during use with the toothbrushing pattern reference data orreference values is used for giving feedback to the user by the outputdevice 27. The monitoring device 18 may be configured to automaticallyinform the user about the results of the brushing, using a LED, aplurality of LEDs, or a display by indicating the result for apredetermined time period after the brushing has completed, asdetermined by a timeout, return to a base, or a switch, for example.

Instead of a visual indicator, the output device 27 may consist of anindicator which produces sound, such as a buzzer producing apredetermined beep, or a speech generator producing instructions aftertoothbrushing. Such a buzzer or speech generator may be used to indicateeither a successful or unacceptable brushing. In this way, the user maybe provided with immediate feedback about the brushing.

In some embodiments, the monitoring device of FIG. 5 may include a timer28 to measure the duration of brushing in a specific teeth region. Thisenables a comparison to be carried out with a reference valuerepresenting a reference duration as to whether or not the user hasbrushed a teeth region for long enough.

The monitoring device 18 of FIG. 5 may also include an interface 22 forforwarding the result of the comparison to a remote device where theoutput device 27 and/or a separate brushing data storage unit islocated. Consequently, the user may be given feedback by an outputdevice located locally in connection with the signal conditioner and thecomparator, or alternatively by an output device that is remotelylocated, or via both local and remote output devices.

In the case of a wired interface to a remote device, the interface 22may include electrical contacts, which are used by the monitoring device18 for communication with the remote device. Alternatively, in the caseof a wireless interface, the interface 22 may include a radiotransmitter for transmitting the measurement result via a radio path tothe remote device.

The monitoring device 18 also includes an input device 21 for receivinguser inputs, like a push button for user inputs for example forselecting a mode (e.g. teaching, brushing, memory scrolling) orindicating the start or stop of events. Such inputs may be used forsetting the monitoring device 18 into a teaching mode, which may be usedfor collecting the user's own preferred brushing pattern data. The firstmode may be continuous, meaning that data is stored as reference valuescontinuously, including the toothbrushing patterns measured, or it maybe used to store data selectively. Selective data may be used underdental hygienist, dentist or parental supervision to insure adequatebrushing, for example. After actuation of the input device 21, theacceleration sensor 25 is configured to measure and forwardtoothbrushing pattern data (for example, data relating to an inclinationof a toothbrush) to the signal conditioner 23, which may process it andstore it in the memory 26 for subsequent use during use of thetoothbrush.

The acceleration sensor 25 measures toothbrushing patterns forcomparison with reference data when the monitoring device 18 is in asecond mode. The teaching mode allows the user to store individualtoothbrushing pattern reference data in the memory 26 as referencevalues. For example, after pressing the input device 21, the user usesthe toothbrush to brush his or her teeth as thoroughly as desired. Asecond actuation of the input device 21 may end the first mode. Theresult is that toothbrushing pattern reference data indicating angles atwhich this particular user holds the toothbrush during use is stored inthe memory 26 as preferred toothbrushing pattern reference data orreference values. In addition, the reference data may also indicate thetime used, the number of brushing cycles, and the brushing order(transfer from one position to another). This individual toothbrushingpattern reference data may be used for analyzing how thoroughly thisparticular user will brush his or her teeth in the future during dailyuse. The fist mode therefore allows the user to take into accountindividual behaviour (the toothbrush or the user's head is held atindividual angles, for instance) while brushing the teeth.

Above it is by way of example assumed that the monitoring deviceproduces and stores the toothbrushing pattern reference data in thememory once the monitoring device 18 is set to the teaching mode and thetoothbrush is being used. However, an alternative to this is thatpredefined toothbrushing pattern reference data is produced in anexternal device and copied to the memory 26 of the monitoring device 18for subsequent use as reference data or reference values while themonitoring device is utilized during daily toothbrushing.

When the toothbrushing monitoring device 18 is used in daily use, acomparison may be made with the reference data maintained in the memory26 of the monitoring device 18. Additional reference data may berecorded to replace or aggregate with the first reference data. Suchtoothbrushing patterns may be stored either individually or collectivelyas toothbrushing pattern reference data in a recording device. Forexample, a user, in one particular brushing session, may store theproduced toothbrushing patterns in the recording device as referencedata. Alternatively, the user may add such reference data to acumulative toothbrushing pattern reference data.

Individual toothbrushing pattern reference data may be stored for aplurality of persons in the memory 26 of the monitoring device 18. Inone example, an identifier of the person who used the toothbrush duringthe teaching mode is stored in the memory together with thetoothbrushing pattern reference data. In one example, this identifier isassociated with an individual's brush head 19 on a device having onedetachable brush head for each individual user. This is advantageouswhen several persons use the same toothbrush or actually the same handleof a toothbrush (with their own personal attachable brush parts, such asa brush head). In such a case, the monitoring device 18 may be able toautomatically identify the person using the toothbrush by selecting fromthe memory 26 the toothbrushing pattern reference data that best matchesthe data produced during the use of the toothbrush. Alternatively, thetoothbrush may include an interface which allows the user the ability toenter his or her identifier, or the identifier is coded in the brushhead interface in order for the monitoring device 18 to be able toselect the correct toothbrushing pattern reference data from the memory26. The input device 21 may be used as such an interface.

The monitoring device 18 may be configured to auto-calibration on thebasis of the sum of low-pass-filtered acceleration vector suma=√(axlp²+aylp²+azlp²)=1 g, where axlp, aylp and azlp are thelow-pass-filtered acceleration components in orthogonal directions x, y,and z in the brush coordinate system respectively.

All parts of the monitoring device 18 may be encapsulated with eachother and/or integrated into or attached to the body of an electrical ormanual toothbrush. Alternatively, a radio transmitter may be arrangedseparately from the other parts, for instance, in a battery charger,cradle or base of the electrical toothbrush. In such an example, theinterface may include contact terminals in the toothbrush which areconnected to the corresponding terminals in the battery charger forforwarding the result of the comparison via a wired connection to thetransmitter in the battery charger or by induction or short rangewireless communications. The radio transmitter in the battery chargerthen transmits this comparison result further via the wireless radioconnection to the remote device.

FIG. 6 is a flow chart illustrating operation of a monitoring device.

In step 30, the user starts to brush a predetermined teeth region or ateeth region indicated by the user. The alternatives are, for instance,that the teeth regions are always brushed in the same order, that themonitoring device for each new teeth region indicates by the outputdevice 27 which region should be brushed, or that the user by using theinput device 21 indicates the teeth region R-U, L-U, R-D or L-D thatwill be brushed. In any case, the monitoring device 18 knows the teethregion that is being brushed, which in this example is assumed to beregion L-U.

In this example, it is assumed that a timer 28 is used to measure abrushing duration for a teeth region, e.g. how many seconds the userspends brushing the region in question, although a timer is notnecessary in all embodiments. If a timer is used, an alternative is touse three timers, one for each surface of a teeth region. Consequently,in step 31 the timer 28 is initiated and started and the teeth surfacespecific counters are initiated (such as set to zero). In the followingexplanation, it is by way of example assumed that three teeth surfacespecific counters are provided, one for the outer teeth surface 2, onefor the inner teeth surface 6, and one for the masticating surface 10.

In step 32, the acceleration sensor 25 produces signals that the signalconditioner 23 receives and processes. The signal conditioner 23low-pass-filters the signals (ax, ay, az) to eliminate noise andacceleration hazards. In addition the acceleration signal is stronglylow-pass-filtered, which gives a signal with no acceleration but onlywith earth's gravity and acceleration sensor offset and gain error.Maximum and minimum values of this signal are used to auto-calibratesensor parameters of the three axes X, Y and Z (1 g=9.81 m/s2=free fallacceleration in earth's gravity field) as follows:

ax0(=offset)=(axmax+axmin)/2 is calibrated to 0 g,

axgain=(axmax−axmin)/2 is calibrated to 1 g,

ay0(=offset)=(aymax+aymin)/2 is calibrated to 0 g,

aygain=(aymax−aymin)/2 is calibrated to 1 g,

az0(=offset)=(azmax+azmin)/2 is calibrated to 0 g, and

azgain=(azmax−azmin)/2 is calibrated to 1 g.

Now, during brushing, the X and Z components of the stronglylow-pass-filtered signal directly give the inclination of the brush inearth's gravity field. The Y acceleration is then high-pass-filtered bysubtracting the strongly low-pass-filtered signal from the original one(ayhp=ay−aylp). For this signal threshold levels are set. Once apositive threshold is crossed and a negative one as well within apredetermined time limit, a brushing cycle is identified in step 32. Inthis example a specific acceleration, a double level crossing, in otherwords two Y accelerations in opposite directions within a specified timeframe, indicates a brushing cycle. At this stage step 33 is enteredwhere the current strongly low-pass-filtered X and Z components areanalyzed. These components are used in step 33 to determine which teethsurface 2, 6, or 10 was brushed with the identified brushing cycle. Thememory of the monitoring device maintains a sample X and Z pair for eachteeth surface 2, 6, and 10 of the teeth region L-U (and also for allother teeth regions). Therefore, the brushed teeth surface is determinedto be the one whose sample X and Z pair best matches the currentstrongly low-pass-filtered X and Z components. The teeth surfacespecific counter of the identified teeth surface is used to register thebrushing cycle for the identified teeth surface 2, 6 or 10 in step 34,for instance by incrementing the counter with one. Physically the teethsurface specific counters may be implemented as predetermined memorylocations in memory 26.

In step 35, a check is made to determine if brushing of the same teethregion L-U continues, or if the monitoring device has signalled to theuser that brushing of the teeth region should end (for instance byindicating with the output display that the brushing of teeth region L-Uis accepted), or if the user has used the input device 21 to indicatethat the brushing of the teeth region has ended.

Once eventually it is determined in step 35 that the brushing of thecurrent teeth region has ended, step 36 is initiated. In step 36, thecomparator 24 compares the registered number of brushing cycles for eachteeth surface specific counter with the corresponding reference valuesin the memory 26. In addition, although not necessary in allembodiments, in this example the timer 28 is checked to determine theduration of the brushing of the teeth region L-U with a correspondingreference value in the memory 26. If all the teeth surface specificcounters have registered a number of brushing cycles that with asufficient accuracy corresponds to the reference values, and in thisexample, also the brushing duration with a sufficient accuracycorresponds to the reference value in the memory 26, it is indicated bythe output device 27 in step 37 that the brushing of teeth region L-Uhas been accepted. Otherwise it is indicated in step 37 by the outputdevice 27 that the brushing of teeth region L-U has not been accepted.

The sufficient accuracy required in the comparison in order to acceptthe brushing result depends on the implementation. One alternative isthat if all teeth surface specific counters register a number ofbrushing cycles which is at least 60 to 80% of the reference value forthe teeth surface in question, and similarly the duration (if used) ofbrushing as measured by the timer is at least 60 to 80% of thecorresponding reference value, the brushing of the teeth region inquestion can be accepted.

Finally, in step 38, it is determined whether or not teeth regions stillremain that need brushing. If not, the process may end. Otherwise, steps30 to 38 are repeated for a following teeth region.

In addition to the previously described features, the monitoring devicemay also utilize the output device 27 to indicate for the user when thetoothbrush has been worn out and consequently reached an end of life. Inthis way the user may be informed of when to purchase a new toothbrushor toothbrush head. One alternative to obtain such information is thatthe monitoring device is configured to count the number of totalaccumulated toothbrushing cycles, and to indicate with the output device27 that the end of life of the toothbrush has been reached once a brushspecific preset reference number of toothbrushing cycles has beenreached. In case of an embodiment where the same monitoring device canbe used with another toothbrush or toothbrush head, the user may in thiscase be given an opportunity to reset the count of the accumulatedtoothbrushing cycles once the toothbrush or toothbrush head has beenrenewed.

Alternatively the monitoring device may be configured to compare apresent brushing acceleration spectral distribution to a brush specificpreset reference distribution, and to indicate with the output device 27an end of life of the toothbrush based on said comparision.

It is to be understood that the above description and the accompanyingfigures are only intended to illustrate the present invention. It willbe obvious to a person skilled in the art that the invention can bevaried and modified without departing from the scope of the invention.

What is claimed is:
 1. A tooth brushing monitoring device for use with atoothbrush during tooth brushing, said monitoring device comprising: aninput device for taking user inputs, an acceleration sensor forproducing signals during tooth brushing, a signal conditioner receivingand processing signals from the acceleration sensor, said signalconditioner, while said toothbrush and monitoring device is used forbrushing a predetermined or user indicated teeth region comprising aplurality of predefined teeth surfaces, identifies a brushing cyclebased on a specific acceleration of a brush head of said toothbrush in alongitudinal direction of said brush head, and in response to anidentified brushing cycle, said signal conditioner identifies thepredefined teeth surface that was brushed with the identified brushingcycle based on an inclination of the monitoring device in gravity duringthe brushing cycle, and registers the identified brushing cycle of theidentified teeth surface with a corresponding teeth surface specificcounter, a memory for maintaining at least one teeth surface specificreference value for each predefined teeth surface of each teeth region,a comparator which compares a number of brushing cycles registered byeach of the teeth surface specific counters during brushing of the teethregion with the corresponding teeth surface specific reference valuesmaintained in said memory, and an output device which indicates that thebrushing of the teeth region in question has been accepted, if thecomparator indicates that the number of brushing cycles registered byeach teeth surface specific counter during the brushing of the teethregion in question corresponds with a predefined accuracy with thecorresponding reference values for the teeth region in question.
 2. Themonitoring device according to claim 1, wherein said monitoring deviceadditionally comprises a timer which during brushing of saidpredetermined or user indicated teeth region measures a duration of thebrushing of the teeth region in question, said memory additionallymaintains a duration reference value for each teeth region, saidcomparator additionally comparing the duration measured by said timerduring brushing of the teeth region with the corresponding durationreference value maintained in said memory, and said output deviceindicates that brushing of the teeth region in question has beenaccepted only if also the duration measured by said timer duringbrushing of the teeth region with a predetermined accuracy correspondswith said corresponding duration reference value.
 3. The monitoringdevice according to claim 1, wherein said monitoring device isresponsive to a predetermined user input with said input device forentering a teaching mode, wherein the signal conditioner during brushingstores at least said teeth surface specific reference values for theteeth regions in said memory for use by said comparator in comparisonduring subsequent toothbrushing.
 4. The monitoring device according toclaim 1, wherein said longitudinal direction of said brush head defininga Y-axis, a direction of bristles of said brush head defining an X-axis,which is perpendicularly oriented as compared to the Y-axis, and aZ-axis is perpendicularly oriented as compared to the X-axis and theY-axis, said signal conditioner subjects said signals from theacceleration sensor to a strong low pass filtering, said signalconditioner determines the inclination of the monitoring device ingravity based on a measured acceleration in the X and Z directions asindicated by the strongly low pass filtered signals, said signalconditioner subjects said signals from the acceleration sensor to highpass filtering for identifying a brushing cycle as Y-accelerationindicated by the high pass filtered signal.
 5. The monitoring deviceaccording to claim 1, wherein the signal conditioner is configured toidentify acceleration of the brush head in the longitudinal direction asa brushing cycle only if two accelerations in opposite directions areidentified within a predetermined timeframe.
 6. The monitoring deviceaccording to claim 4, wherein said signal conditioner comprises at leastone filter of a type: y(t)=y(t−1)*(1−1/k)+x(t)/k, where y(t) is outputat time step t, x(t) is input at time step t and k is a filter factorrespectively.
 7. The monitoring device according to claim 4, whereinsaid signal conditioner comprises at least one filter of a type:z(t)=x(t)−y(t), where z(t) is output at time step t, x(t) is input attime step t and y(t) is a low pass filtered signal respectively.
 8. Themonitoring device according to claim 7, wherein said at least one filteris a digital filter.
 9. The monitoring device according to claim 4,wherein the monitoring device is configured to auto-calibration based ona sum of low pass filtered acceleration vector suma=√(axlp²+aylp²+azlp²)=1 g, where axlp, aylp and azlp are the low passfiltered acceleration components in orthogonal directions x, y and zrespectively and g is earth's gravity.
 10. The monitoring deviceaccording to claim 1, wherein said monitoring device comprises awireless or wired data transmission interface for taking user inputsfrom said input device via said interface and/or for transmittinginformation of a result of said comparison to said output device viasaid interface.
 11. The monitoring device according to claim 1, whereinsaid output device includes at least one of the following: a LED, adisplay, a sound generator or a speech generator.
 12. The monitoringdevice according to claim 1, wherein the monitoring device is configuredto count a number of total accumulated toothbrushing cycles, and toindicate with the output device an end of life of the toothbrush once abrush specific preset reference number of toothbrushing cycles has beenreached.
 13. The monitoring device according to claim 1, wherein themonitoring device is configured to compare a present brushingacceleration spectral distribution to a brush specific preset referencedistribution, and to indicate with the output device an end of life ofthe toothbrush based on said comparison.
 14. The monitoring deviceaccording to claim 6, wherein said at least one filter is a digitalfilter.